Viscosimeter



K. FISCHER vlscosxmxn Fund Jan; 24. 1945 Aug. 26, 1947.

3 Smets-Sheet 2 n .llllillllllnlll llllllllll ci 14|,l4llflllfllllflllln 'In lilllllllllf ci z3(- /fzanny K. FISCHER VISOOSIIBTBR Aug. 2s, 1941.

Filed Jan. 24. 1945 3 Smets-Sleat 3 Zahn/ 'INVHvmL Knaur Farm v BY PefentedeAug. 26, 1947 e -aizasss y Q vrscosnuuzrim.

'Kenna rachel, ariege valley, Pa., namur i Fischer & Porter Company, llatboro, Pa., a vcorporation of Pennsylvania Application January 24, 194s, serial Ne. 514,363

The present invention relates to a certain `new and useful apparatus for determining the viscosity of fluids in motion and it relates Amore particularly tothe determination of the viscosity of a fluid while such fluid is in. motion, as, forl example. while said iluidis passing through a pipe-line.

An object of -the present invention is to provide a simple, dependable and accurate apparatus for determining and maintaining a constant check upon the viscosity of a fluid in motion, as, for instance, fluids in transit in industrial chemical processes, without having to remove any of the. fluids` from the line. A further object ofthe present invention is to provide dependable and inexpensive apparatus for measuring and` maintaining a constant check upon viscosity of uids in motion, as, for instance, fluids in transit ln pipe-lines in industrial chemical plants.

Other objects and advantages of the present invention will be apparent in the following detailed description, appended claims land accompanying drawings.

The present application is a continuation-1in-l part o f my application Serial No. 535,626, filed lmw 15, 1944.

Generally speaking, according to my present invention, the viscosity of a flowing fluid can be determined by passing the uid through a rotameter tube wherein are disposed two separate metering floats; one float being insensitive to, and unaffected by, variations in viscosity (so that its position is determined solely by the rate-of-l can be determined by the corresponding varia?-v tions in the difference of the positions of the two floats.

The present invention further provides a directreading viscosimeter wherein the rate-of-flow is adjusted to a predetermined value (as indicated by the position of the viscosity-insensitive float opposite a predetermined reference point) whereupon the viscosity of the flowing fluid is indicated directly by the position of the viscosity sensitive float relative to a suitably calibrated scale.

For the purpose of illustrating the invention, there are shown in the accompanying drawings forms thereof which are at present preferred, although it is to be understood that the various instrumentalities of which the invention consists can be variously arranged and organized and that 15 claims. (el. '1s-ss) 2 the invention is not limited to the precise arrangements and organizations of the instrumentalities as herein shown and described.

Referring to the accompanying drawings in which like reference charactersindicate like parts throughout: v v

Figure 1 represents' a front elevationalzview of one embodiment of the present invention.

Figure 2 represents a'vertical cross-,sectional view of the embodiment of Figure 1.

Figure 3 represents a horizontal cross-sectional view generally along the line 3-3 of Figure 2.

Figure 4 represents a horizontal cross-sectional view generally along the line 4-4 of Figure 2.

Figure 5 represents a vertical cross-sectional view of another embodiment of the 'present invention.

Figure 6 represents a horizontal.cross-sectional view generally along the line G-.6 of Figure 5.

Figure '7 represents a horizontal cross-sectional' view generally along the line l--l of Figure 5.

Figure 8 represents a schematic elevational view, on an enlarged scale, of the iloat assembly .of Figure 5, parts being brokenv away better to reveal the construction thereof.

Figure 9 represents a vertical cross-sectional view of still another embodiment of the present invention.

'Figure 10 represents a horizontal cross-sectional view generally along line l-lll oi' Figure 9.

`Figure 11 represents a horizontal cross-sectional l l ttings 23A and -24 are detachably connected at the mounted on rthe outside of the fittings thereby to Amaintain said collars upon said fittings.

Gaskets or packing rings 21 are provided about n the ends of the metering tube 20; the gaskets 2l being adapted to be axially compressed and radially-expandedupon tightening of the collars 25 and 26 thereby to provide a fluid-tight seal 4intercireumferentiany-distributed mediate the ends of the metering tube 29 and the heads or ttings 23 and 24.

The lower head 24 is provided with an inlet opening 28 adapted for connection to a pipe-line or the like and has a conduit 29 extending vertically therethrough; `theconduit 29 connecting with thejinletopening 28' and communicating with the lower end lol the metering tube 29.

The upper head 23 is provided with an outlet 'opening 39 and has a vertical conduit 3| extending therethrough; the conduit 3| connecting with provide parallel convex float-guiding shoulders or the outlet opening 39 and communicating, at its lower end, with the upper end of the metering Al generally cylindrical extension tube 34 of glass or, other suitable transparent material is disposed below the metering tube 29 and in generally vertical alignment therewith. The exten-- siontube 34 is enclosed within a metal housing 35 having windows 36 therein. f

The upper end of the extension housing 35 is externally screw-threaded and is adapted adjustably to-be engaged by a collar 31 provided at the lower end of the head 24.

- The lowerend of the extension housing 35 is also externally screw-threaded and is adapted to be operatively engaged by the screw-threaded collar 38 of a lowermost extension ntting 39.

Gaskets'or packing rings 49 are provided about the extension tube 34 adjacent the ends thereof; the gaskets 49 being adapted to .b e axially compressed and radially-expanded upon tightening of the collars 31 and 38 thereby to provide fluidtight seals intermediate the ends ofthe extension tube 34 and the ttings 24 and 39. 'I'he gaskets 49 (as well as the gaskets 21) may be backed by metal washers which are peripherally supported upon inwardly-extending annular shoulders formed on the housing35 as we ll as on the housing 2 I).

The extension tting 39 is vertically apertured to permit cleaning of the extension tube 34; the lowermost end of the tting 39 being closed by a screw-threaded plug 4|. A sleeve 42 extends upwardlyvwithin the lfitting 39 and into the lowermost end of the extension tube 34; the sleeve 42 serving as a bottom stop for a metering float to be hereinafter described.

The metering tube 29, which is the subject of my co-pending application Serial No. 535,624, led May 15, 1944, is downwardly tapered throughout most of its'length, that is, from its upper en'd to thepoint 43;y a cylindrical inner bore 44 being provided at the lowermost portion of the tube 29, that is, from the point 43 to the lower end of the tube.

A plurality (for example three) of uniformlyinwardly-protruding axially-extending float-guiding beads 45 are provided upon the tapered inner bore of the metering tube 20. The tips of the beads 45 extend generally parallel to the axis of the tube 29 and indirect continuation of the cylindrical inner 4bore 44. That is, the beads 45 are relatively pronounced at their upper ends and gradually becomeles's pronounced downward along the tapered bore of the tube until they fade out completely at the'point 43. As shown particularly in Figure The upper end of the conduit 3| lands of small circumferential dimension ywhich serve to center the metering lioats to be hereinafter described along the axis of the tube 29 and to provide substantially frictionless centering support for the floats A metering iioat 45 is disposed within the tubes 29 andA 34 as shown particularly in Figure 2. The oat 46 includes an uppermost flow-constricting head portion 41 which is operatively disposed within the metering tube 29. The head portion 41 is in the form of a frusto-conical or cup-v shaped member opening toward the lower end of the metering tube 29. The head portion 41 may be provided with a beveled periphery 48; the periphery 48 passing close to the tips of the floatguiding beads 45 so that the head 41 is maintained in position generally at the axis of the metering `tube 20. The metering neat 4|iL also includes a lowermost generally cylindrical weightgivng body portion 49 which is disposed within the cylindrical extension tube 34; the head 41 ahd the body portion 49 being connected by a thin elongated rod 59 passing through the conduit 29 of the ntting 24.

It is apparent that the metering-float 46 is maintained. in position generally axially of the metering tube 29 and is kept from "wobbling by the novel supporting and guiding structure herein described. That is, the construction described' construction described above renders the metering iioat 49 relatively insensitive to, and unaffected by, variations in the viscosity of the fluid. y'I'hus,the position of the flow-constricting head 41 of the metering float 46 within the metering tube 29 is determined solely by the rate-of-ow of fluid upwardly through said tube; the float 4S remaining generally constant at constant rate-ofow regardless of variations in iluid viscosity.

I also provide, within the metering tube 29, a second float 5| which may be in the form of a simple imperforate cylinder having a diameter slightly less than that of the cylindrical bore 44 of the tube 29 whereby said float 5I is guided and centered by the beads 45.

The float 5| is relatively sensitive to, and affected by, any variations in the uid viscosity.

Thus, thev position of the float 5| within the metering tube 29 is the result of viscosity-effect as `well as rate-of-flow. In other words, the height Both iloats 46 and 5| have a specific gravity i the iloat 46 resting against the lower stop sleeve 42 and the iloat 5| resting against the top of the head portion 41 of the iloat 46. As is well known in the art, upward flow of uuid through the tube zo win 'nd to lift the metering iioats upward within said tube. However, the viscosity eiIect of the uid will tend to lift the float 5| higher within vthe tube 20 than the iloat 46; the greater viscosity, the greater the differential in the positions of the two floats.

In' the embodiment of Figures lto 4, I prefer to determine viscosity directly -by adjusting (either manually or automatically) the rate-of-ow of the uid to a predetermined value at which the periphery of the ilow-constricting head portion 41 of the metering oat 46 is directly opposite the reference arrow V53 of the scale 52 as shown in Figure 1. With the oat`46 in this position, the scale -52 is so calibrated with reference to the iluid being metered, that the position of the float -5| relative to the scale 52 will be a direct indication of the viscosity of 'the fluid.

Furthermore, variations in the position of the oat 5I (while the rate-of-ow and the position of the float 46 are maintained constant) indicate corresponding variations in the viscosity of the ilowing fluid.

In this way, a`constant vcheck cancbe maintained upon the viscosity of the flowing fluid.

It is obvious that the heads or fittings l23 and 24 can be rotated throughout horizontal planes to permit connection of the inlet and outlet openings 28 and 30 to horizontal pipe-lines extending in any direction relative to each other. This rotation of the fittings 23 and 24 is done before the collars 25and 26 are fastened in position after which the inlet and outlet-openings are locked in predetermined relationship to each other by tightening of the collars.

, In Figures 5 to 8 I have shown another embodiment of the present invention wherein I may provide a vertical metering tube |20 (to be hereinafterfdescribed in detail) having its lower and lationship upon the head |26 by means of a pluralityv (for example four) of spacer frods or posts 42.

The metering tube |20 is downwardly tapered throughout most of its length, that is, from its upper-end |22 to the point |43; a cylindrical inner bore |44 being provided at the 'lower portion l0f the tube |20, that is, from the point |43 to the lower end |2I.

A plurality (for example three) of uniformlycircumferentially-distributed inwardly-protruding axially-extending oat-guiding beads |45 are provided upon the tapered inner bore of said upper ends.|2| and |22 disposed in fluid-tight relationship Within stuing-boxes |23 and |24 of lowerand upper rotameter "heads or fittings |25and |26 respectively; fluid-tight seals being provided by lower and upper packing rings |21 and |26 and lower andupper stuffing-glands |29 and |30 in conventional manner. The heads |25 and |26 are heldin spaced relationship by a plurality (for example four) of spacer rods vor posts |3|; the lower head is adapted to be screwthreadedly connected to a horizontal inlet pipeline |32 while the upper head |26 -is ladapted to bepscrew-threadedly connected to a horizontal Y outlet pipe-line I 33.

` A generally cylindrical extension tube or chamber '|34 is mountedupon'the upper end of the head |26 in axial alignrnent with the me- The lower end of the extension tube |34 is connected in'fluid-tight relationship4 within an upper stumng-box |35 formed in said head |26 by means of packing rings |36 and a stumng-gland |31.

' The upper end of 'the extension tube |34 is? mounted in fluid-tightrelationship within the stufilng-box |38 of an uppermost tting |39`by means'ofvpacking rings |40 and 'a stufllng glaid |4|'; the iitting |39 being mounted in spaced remetering tube l20. The tips of the beads |45 extend generally parallel to the axis of the tube |20 and in direct continuation of the'cylindrical inner bore |44. That is, the beads |45 are relatively pronounced at the .upper larger end of the tube |20'and gradually become less pronounced downward along the tapered bore of the tube until they fade out completely at the point |43.

As will be hereinafter described, the beads |45 provide parallel Vfloat-guiding shoulder or lands which serve to center the metering oat along the axis of the tube.

A main metering float |46 is mounted within the tubes |20 and |34 as shown particularly in Figure 5.

The float 146, as can includesa lowermo'st flow-constricting head portion |41 which is operatively disposed within the metering tube |20. 'Ihe head portion |41 is in the form of a conical or cup-shaped member opening toward the lower inlet end |2| of the metering tube |20. The head portion |41 may be provided with a beveled periphery |48; the periphery |48 passing close to the tips of the float-guiding beads 45 as can be seen particularly in Figure 7 so that the metering head |41 is maintained in position generally at the axis of the metering tube |2||.4 A

The main metering iloat |46 also includes an uppermost Weight-giving body portion |49 which is disposed within the extension tube |34; the metering head |41 andthe body portion |49 being connected by a` thin elongated rod |50.

' It is apparent that the main metering float' l|46 is maintainedV in position generally axially of the metering tube |20 and is kept from Wobbling by the novel supporting and guiding structure herein described. That is, the novel construction described hereinabove, prevents wobbling or tilting or other undesirable oscillation of the metering loat due to the fact that the lowermo'st yhead portion |41 is -centered by the float-guiding beads |45 While -the uppermost body portion |49 and the connecting rod |50 are centeredbythe extension tube |34. f I

Where the extra weight `is not` needed, lthe Weight-giving portion |49'may be omitted entirely; in which case, the extension tube 34 is made small in diameter so as more snugly to receive andguide the upwardly-extending rod |50. l

As is well known in thev art, the' flow-constricting head'portion |41 will movefvertically within thernetering tube |20 responsive to variations in lthe rate-of-flow of fluid upwardly therethrough;

. the position of the head portion |41 within the A ly through the tube |20. p y As' discussed hereinabove, the cup-shaped mebest be seen in Figure 8,

of the rate-of-fiow of uid upwardly through said tube.

I also provide, within the metering tube a secondary float |5|. 'The secondary float |5| which is generally in the form of a tear-drop having a slightly enlarged ow-constricting periphery |52 (the periphery |52 having the same diameter as the periphery |48 of the main float |46) is provided with an axial opening |53 therethrough whereby the secondary float |5| can be slidably mounted .upon the thin elongated connecting rod portion |50 of the main float |46. To

facilitate installation and removal of thesecondary float |5|, the body portion 49 of the main float |46 may be made removable from the upper end of the connecting rod |50.

The secondary float |5| is relatively sensitive to, and affected by, variations in the fluid viscosity. Thus, the position of the secondary float |5| within the metering tube |20 is the result of viscosity-effect as well as rate-of-ilow. In other words, the height of the secondary oat within the tube |20 is an indication of the cumulative eilect of both rate-of-flow and viscosity. 4

It is apparent that the difference in positions of the main float |46 and the secondary float |5| will be an indication of the viscosity of the fluid and that variations in this diierence will be an indication of corresponding variations ln 4the viscosity of the fluid.

-In order that the secondary float |5| be, at all measurable flow-rates, somewhat above the head portion |41 of the main metering float |46, I, prefer to make the secondary float slightly less in weight than the main float.

Where the secondaryfloat |5| is made slightly less in weight than the main float |46, it is necessary to provide separate scales |54 and |55 for the secondary float and the main float to compensate for the lighter floats tendency to rise higher at a given rate-of-fiow. The scales |54 and |55 may be either direct reading scales as in the embodiment of Figure 1 to show viscosity directly or, alternatively, they may be calibrated in arbitrary units from which viscosity can be calculated by reference to a suitable table or chart.

It is apparent that the viscosity of the flowing fluid as well as variations in such viscosity can quickly and easily be determined by simply reading off the positions of the two oats relative to their respective scales.

In Figures 9 to 12 I have shown still another Amodification of the present invention. In this Since the metering tube |20-a does not have.

iloat-guiding beads formed thereon, it is neces- 8 sary to provide a guide-rod |61 (extending axially along the metering tube |20-a and the extension tube |34)v which is mounted at its ends in the lower head |25 and the uppermost fitting |39; screw-threaded adjustment means being provided for said guide-rod |61 at its lower and upper ends as at |68 and |69 respectively.

Lower and upper spiders |10 and |1| may be provided upon the guide-rod |61, the lower spider |10 being generally adjacent the lower end of the metering tube |20 and the upper spider |1| being generally adjacent the upper end of the.

extension tube |34. y

In this embodiment, I may provide a main metering iloat |12 having a lowermost conical flowconstricting head portion |13 disposed within the metering tube |20-a, an apertured weight-giving body portion |14 disposed within the extension tube |34 and a thin elongated tube |15 connecting the head portion |13 and the body portion |14.

As can be seen particularly in Figure 12, the oat |12 is slidably mounted upon the guide-rod |61 and is adapted for free up-and-down movement therealong. The metering float |12 is generally insensitive to, and unaffected by, variations in fluid viscosity so vthat its position within the metering tube 20-a is determined solely by the rate-of-ow of fluid passing upwardly through said tube. l

A secondary iloat |16 having an axial opening |11 therethrough is slidably mounted upon the connecting tube |15 of the main float :|12: the oat |16 being disposed within the metering tube |20-a above the flow-constricting head |13 of said main float |12. if

The float |16 is generally cylindrical with a tligeled upper edge |18 and a lower tapered tail The secondary float |16 is sensitive to, and affected by, variations in fluid viscosity so that its position within the tapered metering tube |20-a is an indication of the cumulative effect of both viscosity and rate-of-ilow. As described hereinabove, the difference in height of the two floats is an indication of the viscosity of the their respective scales) is an indication ofI the viscosity and that variations in this difference indicate corresponding variations in the fluid viscosity.

While for purposes of simplicity of illustration, the scales |54 and |55 have been shown as disposed on opposite sides of the metering tube, the present invention contemplates that the scales can be arranged in different ways. Thus, for example, the scales may be close to each other adjacent the front part of the tube so that the position of the floats can be read olf against the scales by observing the floats through the small space intervening the scales.

All of the metering floats described hereinabove have a specific gravity substantially greater than thatl of the fluids being metered so that they are not cappreciably aifected by and are relatively insensitive to any changes in speclc of the main gravity of the fluid as mightv occur during passage 'I of the fluid through the pipe-line or the like.

The present invention may be embodied in other specific forms without departing from the spirit or essentialattributes thereof, and it is therefore desired that the'present embodiments be considered in all respects 'as illustrative and not restrictive, reference being had to the appended claims rather than to the foregoing description to indicate the scope of the invention.

Having thus described the invention, what I- claim as new and desire to protect by Letters Patent is:

1. A device for determining the viscosity of ar moving fluid vcomprising a vertical metering tube having vertically-varying cross-sectional area available for fluid flow and adapted for vertical ilow of fluid therethrough, an extension chamber in communication with said metering tube and generally in vertical alignment therewith, a metering float having a flow-constricting head portion disposed within said'metering tube and having a body por-tion disposed Within said extension chamber, said metering float being adapted for free up-and-down movement responsive to varia. tions in rate-of-ilow of fluid through said metering tube, and being relatively insensitive to variations in viscosity of said fluid, and a-second float disposed within said metering tube, said second iloat being sensitive to and affected by variations in both rate-of-ow and viscosity-whereby differences in positions of the two floats will be an indication of the viscosity of said fluid.

2. A device for determining the viscosity of a moving fluid comprising a vertical metering tube having vertically-varying cross-sectional area available for fluid ilow and adapted yfor vertical now of iluid therethrough, an extension chamber in communication with said metering tube and generally in vertical alignment therewith, a metering float having a flowfconstrictingvhead portion disposed within said metering tube and having a body portion disposed withinI said extension chamber, said metering float being adapted for free up-and-down movement responsive to variations in rate-of-flow of fluid through` said meter'- i ing tube, and being relatively insensitive to varitially-spaced axially-extendingv inwardly-protruding beads formed thereon, a cylindrical exy tension tube in communication with said metery ing tube and .generally in vertical alignment therewith, a metering .float having a flow-constricting head portion disposed withinsaid metering tube and having -a ,body portion disposed within 'said extension'tube, said metering float being adapted for free up-and-down movement within said metering tube responsive vto variations in rate-of-'flow of fluid through said metering tubev and being relatively insensitive to variationsin' viscosity of said fluid, and a second float disposed Within said metering tube, saidV second float being sensitive to and aifected by variations in both rate-of-ow and viscosity of said fluid, said 'beads and said extension tube serving to center said first-mentioned float generally along the axis of said metering tube, said second float being centered along theaxis of said metering tube by said beads.

4. A device for determining the viscosity ofa.

fmoving fluid comprising a vertical tapered metering tube havinga plurality of circumferentially-spaced axially-extending inwardly-protruding beads formed thereon, a cylindrical extension tube in communication with said meter. ing -tube and generally in vertical` alignment therewith, a metering float having a flow-.con-

stricting head portion disposed within said metering tube and having a body portion disposed within said extensionY tube, said metering'oat being adapted for free up-and-down movement within rsaid metering tube responsive to variations in rate-of-tlow of iluid through said metering tube and being relatively insensitive to variations in viscosity of said fluid, a second oat disposed within said metering tube, said second iloat being sensitive to and affected by variations in both rate-of-ilow and viscosity of said iluid, said beads and said extension tube serving to center said first-mentioned float generally along the axis of said metering tube, said second float being centered along the axis of said metering tube by said beads, and a scale provided for` said metering tube, said scale having a `referencepoint which with said first-mentioned float is adapted to indicate a predetermined rate-of-ilow of said fluid, said scale being calibrated so that the position of the second float-relative thereto yWill indicate the viscosity of the fluid when the first-mentioned float is opposite said reference point.

5. A device for .determining the viscosity of a moving iluid comprising a vertical metering tube having vertically-varying cross-sectional area availablefor fluid flow and having a'plurality of circumferentially-spaced axially-extending inwardly-protruding float-guiding beads formed thereon, a cylindrical extension tube disposed below. said metering tube and in communication therewith, a metering float having a flow-constricting head portion disposed within said metering tube and having a body-portion disposed within saidextension tube, said metering float being adapted for free yuIJ-and-down movement responsive to variations in rate-of-iiow of iluid upward through said metering tube and being relatively insensitive `to variations in viscosity of wardly-protruding neat-,guiding beads formed said fluid, and a second iloat disposed within said ,metering tube within said first-mentionedfloat;

said second oat being sensitive to and affected by variations in both rate-of-flow and viscosity. 6. A device for determining the viscosity of a moving fluid comprising a vertical metering tube vhaving vertically-varying cross-sectional area available for fluid ow'and having va plurality of circumrerentially-spaced axially-extending inthereon, a cylindrical extension tube disposed y y'below said metering tube and in communication msv therewith, a 4meteringiloat having a `flow-constricting head portion disposed Within said me- -tering tube and having a body portion disposed within s'aid extensionk tube, said metering floatbeing adapted forfree up-and-down movement responsive to variations in rate-of-ilow of iluid upward'through said metering. tube and being relatively-insensitive to variations in viscosityof said fluid, a second float vdisposed withinl said metering tube within said first-mentioned iloat; said vsecondiloat being sensitive to and affected by variations in both rate-of-ow and viscosity, and

amasar a scale for said metering tube, said scale having a reference point and being calibrated so that the position of said second float relative thereto will indicate the viscosity of said fluid when said rstmentioned iloat is opposite said reference point.

17. A device for determining the viscosity of a moving fluid comprising a vertical metering tube having vertically-varying cross-sectional area available for fluid flow, a generally cylindrical extension tube disposed below said metering tube and in communication therewith, a metering float having a ow-constricting head portion disposed within said metering tube and having a body portion disposed within said extension tube, said metering float being adapted for free upand-down movement responsive to variations in rate-of-flow of fluid through said metering tube and being relatively insensitive toyariations in viscosity of said iluid, and second float disposed within said metering tube, said second float being sensitive to and affected by variations in both rate-oi -flow and viscosity whereby the differences in positions of the two oats will indicate the viscosity of said fluid.

8. A device for determining the viscosity of a moving fluid comprising a vertical metering tube having vertically-varying cross-sectional area available for fluid flow, a generally cylindrical extension tube disposed below said metering tube and in communication therewith, a metering float having a flow-constricting head portion disposed within said metering tube and having a body portion disposed within said extension tube, said metering float being adapted for free up-anddown movement responsive to variations in rateof-flow of fluid through said metering tube and being relatively insensitive to variations in viscosity of said fluid, a second float disposed within said metering tube, said second oat being sensitive to and affected by variations in both rate-ofow and viscosity whereby the diierences in positions of the two floats will indicate the viscosity of said fluid, *and means for guiding-said floats generally along the axis of said metering tube.

9. A device for determining the viscosity of a moving fluid comprising a downwardly-tapered vertical metering tube having a plurality of circumferentially-spaced axially-extending inwardly-protruding float-guiding' beads formed thereon, a generally cylindrical extension tube disposed above said metering tube and being in communication therewith, a metering float having'a flow-constricting head portionI disposed within said metering tube and having a weight-giving body portion disposed within said extension tube and having a relatively thin elongated connecting portion intermediate said head portion and extension tube disposed above said metering tube and being in communication therewith, a metering float having a fiow-constricting head portion portion and body portion, said metering oat body portion, said metering float being adapted for free up-and-down movement responsive to variations in rate-of-ow of uid through said metering tube and being relatively insensitive to variations in viscosity of saidiiuid, and an axially-apertured second oat mounted upon said thin elongated connecting portion and being adapted for free up-and-down movement within said metering tube, said second iloat being sensi- `tive to and aifected by variations in both rate-ofilow and viscosity whereby the differences in positions of they two floats will indicate the viscosity of said fluid.

10. A device for determining the viscosity of a moving iiuid comprising a vertical metering tube having vertically varying cross-sectional area available nfor iluid iiow, a generally cylindrical being adapted for freey up-and-down movement responsive to variations in rate-of-ilow of fluid upward through said metering tube and being relatively insensitive to variations in viscosity of said fluid, an axially-apertured second float mounted upon said thin elongated connecting portion and being adapted for free up-and-down movement within said metering tube, said second iloat being sensitive to and affected by variations in both rate-of-flow and viscosity whereby the differences in positions of the two floats will indicate the viscosity of said fluid, and means for guiding said mst-mentioned oat axially along said metering tube.

l1. A device for determining the viscosity of a moving iluid comprising a vertical metering tube having vertically-varying cross-sectional area available for uid flow, a generally cylindrical extension tube disposed above said metering tube and being in communication therewith, a metering float having a fiow-constricting head portion disposed within said metering tube and having a weight-giving body portion disposed within/said extension tube and having a relatively thin elongated connecting portion intermediate said head portion and body portion, said metering float being adapted for free up-anddown movement responsive to variations in rate- ,connecting portion and being adapted for free up-and-down movement within said metering tube, said second iloat being sensitive to and aiected by variations in both rate-of-flow and viscosity whereby the differences in positions of the two floats will indicate the viscosity of said fluid, and means for guiding said first-mentioned oat axially along said metering tube, said lastmentioned means including a thin taut guidewire passing through said first-mentioned metering float and extending along the axes of said tubes.

12. A device for determining the viscosity of a moving fluid which comprises a downwardlytapered metering tube adapted for upward flow of fluid therethrough, a metering float disposed within said tubeand adapted for up-and-down movement therewithin responsive t0 variations in iluid rate-of-flow, said oat being relatively insensitive to variations in tluid viscosity and having a ow-constricting head portion and an elongated stem extending upwardly from said head portion, and a second metering float disposed within said tube, said second oat being sensitive to variations in both rate-of-flow and viscosity, said second float being provided with a central axial opening andbeing mounted upon said stem for free up-and-down movement therealong.

13. A device for determining the viscosity of a moving iluid which comprises a downwardlytapered metering tube adapted for. upward flow of fluid therethrough, a metering float disposed within said tube and adapted for up-and-down movement therewithin responsive to variations in fluid rate-of-ilow, said float -being relatively lnsensitive to variations in uid viscosity and having a ow-constricting head portion and an elongated stem extending upwardly from said head portion, and a second metering float disposed within said tube, said second oat being sensitive to variations in both rate-of-ilow and viscosity, said second iloat being provided with a central axial opening and being mounted upon said stem for free up-and-down movement therealong, said tube being provided with' a plurality of circumferentially-spaced inwardly-protruding axially-extending beads providing parallel line-contacts for oat-guidance.

14. A device for determining the kviscosity of a moving fluid which comprises a downwardly-tapered metering tube adapted for upward iow of fluid therethrough, a metering oat disposed within said tube and adapted for up-and-down movement therewithin responsive to variations `in fluid rate-of-flow, said float being relatively insensitive to' variations in fluid viscosity and a second metering float disposed within said tube above said first-mentioned float, said second oat being sensitive to variations in both rate-of-fiow and viscosity, said tube being provided with a plurality of circumferentially-spaced inwardly-protruding axially-extending beads providing parallel line-contacts for float guidance.

15. A device for determining moving duid which comprises a downwardlytapered metering tube adapted/for upward iiow 14 of fluid therethrough, a metering iioat disposed within said tube and adapted for up-and-down movement therewithin responsive to variations in fluid rate-of-flow, said float being relatively int sensitive to variations in uid viscosity and having a fiow-constricting head portion and an elongated hollow stem extending upwardly from said head portion, a second metering float disposed within said tube, said second iloat being sensitive to variations in both rate-of-fiow and viscosity, said secondoat being provided with a central axial the viscosity of a opening and being mounted upon said stem for free up-and-down movement therealong, and a thin taut guidewire extending along the axis of said.tube and, through saidf stem.

KERMIT FISCHER.

i REFERENCES' CITED The following references are of record in the Germany Feb. 18, 1939 

